Single-grain thin-film transistor using Ni-mediated crystallization of amorphous silicon with a silicon nitride cap layer

被引:31
|
作者
Kim, JC [1 ]
Choi, JH [1 ]
Kim, SS [1 ]
Kim, KM [1 ]
Jang, J [1 ]
机构
[1] Kyung Hee Univ, Adv Display Res Ctr, Seoul 130701, South Korea
来源
APPLIED PHYSICS LETTERS | 2003年 / 83卷 / 24期
关键词
D O I
10.1063/1.1633974
中图分类号
O59 [应用物理学];
学科分类号
摘要
Amorphous silicon was crystallized by metal-induced crystallization through a cap with a Ni area density of 2x10(14) atoms/cm(2) on the cap. The crystallized polycrystalline silicon (poly-Si) shows hexagonal-shaped or disk-shaped grains with average grain size of similar to40 mum. The p-type channel thin-film transistor (TFT) on a single-grain poly-Si exhibited a field-effect mobility of 114 cm(2)/V s, a threshold voltage of -4.7 V and a subthreshold slope of 0.5 V/dec. The gate bias-stressed changes in the TFT performance was found to be greatly reduced compared to the laser-annealed poly-Si TFT. The surface roughness of the poly-Si is 2.35 nm smaller than that of conventional excimer laser-annealed poly-Si (13.1 nm), which appears to be related to better device performance and improved stability. (C) 2003 American Institute of Physics.
引用
收藏
页码:5068 / 5070
页数:3
相关论文
共 50 条
  • [41] CRYSTALLIZATION OF AMORPHOUS-SILICON DURING THIN-FILM GOLD REACTION
    HULTMAN, L
    ROBERTSSON, A
    HENTZELL, HTG
    ENGSTROM, I
    PSARAS, PA
    JOURNAL OF APPLIED PHYSICS, 1987, 62 (09) : 3647 - 3655
  • [42] An assessment of μ-Czochralski, single-grain silicon thin-film transistor technology for large-area, sensor and 3-D electronic integration
    Saputra, Nitz
    Danesh, Mina
    Baiano, Alessandro
    Ishihara, Ryoichi
    Long, John R.
    Karaki, Nobuo
    Inoue, Satoshi
    IEEE JOURNAL OF SOLID-STATE CIRCUITS, 2008, 43 (07) : 1563 - 1576
  • [43] CHARGE TRAPPING EFFECTS IN AMORPHOUS-SILICON SILICON-NITRIDE THIN-FILM TRANSISTORS
    HEPBURN, AR
    MAIN, C
    MARSHALL, JM
    VANBERKEL, C
    POWELL, MJ
    JOURNAL OF NON-CRYSTALLINE SOLIDS, 1987, 97-8 : 903 - 906
  • [44] Mechanics of silicon nitride thin-film stressors on a transistor-like geometry
    Reboh, S.
    Morin, P.
    Hytch, M. J.
    Houdellier, F.
    Claverie, A.
    APL MATERIALS, 2013, 1 (04):
  • [45] Strained Single-Grain Silicon n- and p-Channel Thin-Film Transistors by Excimer Laser
    Baiano, Alessandro
    Ishihara, Ryoichi
    van der Cingel, Johan
    Beenakker, Kees
    IEEE ELECTRON DEVICE LETTERS, 2010, 31 (04) : 308 - 310
  • [46] Inverse staggered poly-Si thin-film transistor with non-laser crystallization of amorphous silicon
    Oh, J. H.
    Ahn, K. W.
    Kang, D. H.
    Park, W. H.
    Jang, J.
    Chang, Y. J.
    Choi, J. B.
    Min, H. K.
    Kim, C. W.
    SOLID-STATE ELECTRONICS, 2008, 52 (03) : 482 - 486
  • [47] RESOLUTION OF AMORPHOUS-SILICON THIN-FILM TRANSISTOR INSTABILITY MECHANISMS USING AMBIPOLAR TRANSISTORS
    VANBERKEL, C
    POWELL, MJ
    APPLIED PHYSICS LETTERS, 1987, 51 (14) : 1094 - 1096
  • [48] Solution processed IZTO thin film transistor on silicon nitride dielectric layer
    Kim, Bong-Jin
    Kim, Hyung-Jun
    Yoon, Tae-Sik
    Kim, Yong-Sang
    Lee, Doo-Hyoung
    Choi, Youngmin
    Ryu, Byung-Hwan
    Lee, Hyun Ho
    JOURNAL OF INDUSTRIAL AND ENGINEERING CHEMISTRY, 2011, 17 (01) : 96 - 99
  • [49] Studies of the new findings in preparing a scaled amorphous silicon thin-film transistor
    Cheng-I Lin
    Yean-Kuen Fang
    Che-Hao Kuo
    Applied Physics A, 2014, 116 : 1655 - 1660
  • [50] 150°C amorphous silicon thin-film transistor technology for polyimide substrates
    Gleskova, H
    Wagner, S
    Gasparík, V
    Kovác, P
    JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 2001, 148 (07) : G370 - G374
12345